Elevated working platform and related methods

ABSTRACT

Elevated work platforms, as well as associated methods, are provided. In one particular embodiment, an elevated platform apparatus is provided comprising a first rail assembly having a pair of rails coupled with a plurality of rungs, a second rail assembly hingedly coupled with the first rail assembly, a platform configured to rest upon a portion of the first rail assembly and the second rails assembly and a cage associated with the platform. The cage may include at least one bar and at least one gate, the at least one gate being configured to swing in a first direction upon a user stepping on to the platform from the first rail assembly, and then swing back to a closed position after the user is standing on the platform. The at least one gate is also limited from being displaced in a second direction, opposite the first direction, beyond the closed position.

CROSS-REFERENCE TO RELATED APPLICATION

This application is a continuation of U.S. application Ser. No.13/748,263, filed Jan. 23, 2013, and entitled ELEVATED WORKING PLATFORMAND RELATED METHODS, which application claims the benefit of U.S.Provisional Patent Application No. 61/589,790 entitled PLATFORM LADDERAND RELAYED METHODS, filed on Jan. 23, 2012, the disclosures of whichare incorporated by reference herein in their entireties.

TECHNICAL FIELD

The present invention relates generally to elevated working platformsrelated methods.

BACKGROUND

Ladders are one type of apparatus conventionally used to provide a userwith improved access to elevated locations that might otherwise bedifficult to reach. One of the advantages of ladders is theirconvenience. Ladders are easily transported from one location toanother, generally easy to set up and use at a specific location, andeasy to store when not in use. Ladders come in many sizes andconfigurations, such as straight ladders, extension ladders,stepladders, and combination step and extension ladders. So-calledcombination ladders may incorporate, in a single ladder, many of thebenefits of multiple ladder designs.

In an effort to provide more secure, safe and stable access to elevatedlocations, users often employ various accessories. For example, planksor other structures are sometimes combined with two or more ladders toact as a platform or scaffolding. In one particular example, so-calledladder jacks are often utilized in conjunction with a pair of ladders toprovide a support for one or more wooden planks (e.g., 2 inch×10 inchplanks or 2 inch×12 inch planks). Such a configuration enables a user towork on an elevated surface that exhibits a larger support surface areathan that of the rung of a ladder and, thus, enables the user to work ina larger area without having to move a ladder multiple times. In anotherexample, an attachment sometimes referred to as a work platform may becoupled to one or more rungs of a ladder in an effort to provide moresurface area for the user to stand on, improving their stability andcomfort. However, breaking down or disassembling such a configuration,moving all of the components and then setting them up again can be timeconsuming and require considerable effort. Additionally, there aretypically no safety constraints used in such a configuration, making theuse of planks a potential safety concern.

It is becoming increasingly common to require users to “tie off” orotherwise secure themselves when using a ladder or other elevatingapparatus on a job site. Such a requirement may be instituted by aproperty owner, by an employer, or by a governmental body such as OSHA(Occupational Safety and Health Administration) to reduce the risk ofinjury from a fall. However, users of ladders (or other elevated supportstructures) sometimes find such requirements to be a nuisance and somemay even try to avoid such requirements. At a minimum, users of a ladderwill typically find that such requirements take additional time, makingthe worker less efficient at completing their task, even if they aresafer while working.

It is also known that many users will often climb higher on a ladderthan is recommended for the specific ladder—sometimes to the highestrung of a stepladder or even on the top cap of a stepladder—even thoughexplicit warnings are provided by the manufacturer of the ladder againstsuch behavior. Climbing beyond the highest recommended rung can make theladder unstable. Additionally, the user may become unstable whenclimbing beyond a recommended height because, for example, they may nothave any additional structure to lean against or grasp with a free handwhile standing at or near the very top of the ladder.

As such, the industry is continually looking for ways to improve theexperience of using ladders and elevated platforms and to provide theusers of such apparatuses with more efficient, effective, safe andcomfortable experiences.

BRIEF SUMMARY OF THE INVENTION

In accordance with the present invention, various embodiments of anelevated work platform, as well as associated methods, are provided. Theelevated platform may provide a relatively large surface area for a userto stand on while working at an elevated height while also providing asafe working environment without the need to continually tie-off or weara harness during the use of the apparatus.

In accordance with one embodiment, an elevated platform apparatus isprovided comprising a first rail assembly having a pair of rails coupledwith a plurality of rungs, a second rail assembly hingedly coupled withthe first rail assembly, a platform configured to rest upon a portion ofthe first rail assembly and the second rails assembly and a cageassociated with the platform. The cage includes at least one bar and atleast one gate, the at least one gate being configured to swing in afirst direction upon a user stepping on to the platform from the firstrail assembly, and swing back to a closed position after the user isstanding on the platform, the at least one gate also being limited frombeing displaced in a second direction, opposite the first direction,beyond the closed position.

In one embodiment, the platform is pivotally coupled with the first railassembly and in selective locking engagement with the second railassembly.

In one embodiment, the at least one gate includes a pair of gatesadjacent one another. Each gate of the pair may include, according toone particular embodiment, a pivoting coupling member having an inclinedengagement surface, wherein the inclined engagement surface, inconjunction with the weight of the gate, biases the gate to the closedposition.

In one embodiment, the first rail assembly includes an outer railassembly and an inner rail assembly slidingly coupled with the firstrail assembly. One or more adjustment mechanisms may be used toselectively lock the inner rail assembly at a specified locationrelative to outer rail assembly.

In certain embodiments, a pulley system may be associated with the firstassembly. For example, a pulley system may include a tension line havinga first, free end and a second end coupled with the outer rail assembly,the tension line being fed through a first pulley coupled to the outerrail assembly and a second pulley coupled with the inner rail assembly.

As with the first rail assembly, according to one embodiment, the secondrail assembly includes an outer rail assembly and an inner rail assemblyslidingly coupled with the first rail assembly. Again, one or moreadjustment mechanisms may be used to selectively lock the inner railassembly of the second assembly at a specified location relative toouter rail assembly of the second assembly. Another pulley system may beassociated with the second assembly.

In one embodiment, a barrier member may be positioned on an interiorsurface of the outer rail assembly at a location adjacent the at leastone adjusting mechanism. The barrier member may be configured andlocated to prevent potential injury to a user's hands or fingers.

In one embodiment, where inner and outer rail assemblies are used, railsof the inner rail assembly are disposed within cross-sectional cavitiesof associated rails of the outer rail assembly. The rails of the outerrail assembly each include a bracket at their upper end substantiallycircumscribing the rails of the outer rail assembly as well as the railsof the inner rail assembly, with the bracket defining a slot locatedalong a surface of the rails of the inner rail assembly.

In certain embodiments, at least one pair of wheels coupled with theapparatus. In one specific embodiment the at least one pair of wheelsincludes: a first pair of wheels coupled with at least one of the firstassembly and the second assembly at a fixed location; a second pair ofwheels coupled with the first assembly, the second pair of wheelsincluding at least one retraction mechanism; and a third pair of wheelscoupled with the second assembly, the third pair of wheels including atleast one retraction mechanism. In one embodiment, each of the at leastone retraction mechanism associated with the second pair of wheels andthe at least one retraction mechanism associated with third pair ofwheels includes a cam cylinder, a push rod, a cam follower and at leastone biasing member.

In one embodiment, a flexible barrier disposed at least partially aboutthe cage. Such a flexible barrier may include netting or a meshmaterial. In one particular embodiment, the at least one bar of the cageincludes a first bar at a first elevation relative to the platform and asecond bar and a second, higher elevation relative to the platform, andthe flexible barrier extends between the platform and the first bar andsubstantially circumscribes the platform except for the location of thepair of gates.

In one particular embodiment, the second assembly includes a pair ofrails and a plurality of rungs, and the cage is defined to include atleast one additional gate, wherein the at least one additional gate isconfigured to be displaced from a closed position upon a user steppingon to the platform from the second rail assembly, and return to a closedposition after the user is standing on the platform. In certainembodiments, the at least one additional gate includes a pair of gatespositioned adjacent to each other.

In accordance with one embodiment, at least one stabilizer coupled withat least one of the first rail assembly and the second rail assembly.

Features, aspects and acts of any of the various embodiments describedherein may be combined, without limitation, with other describedembodiments.

BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWINGS

The foregoing and other advantages of the invention will become apparentupon reading the following detailed description and upon reference tothe drawings in which:

FIG. 1 shows an elevated platform apparatus in a closed or collapsedstate in accordance with an embodiment of the present invention;

FIG. 2 shows the elevated platform apparatus of FIG. 1 in a partiallyclosed or partially collapsed state in accordance with an embodiment ofthe present invention;

FIG. 3 shows the elevated platform apparatus of FIG. 1 in anotherpartially closed or partially collapsed state in accordance with anembodiment of the present invention;

FIG. 4 shows additional details of certain components of the elevatedplatform apparatus shown in FIG. 1;

FIG. 5 shows further details of additional components of the elevatedplatform apparatus shown in FIG. 1;

FIG. 6 shows details of further components of the elevated platformapparatus shown in FIG. 1;

FIG. 7 shows an enlarged portion of an elevated platform apparatusdepicting additional components and mechanisms that may be used inaccordance with an embodiment of the invention;

FIG. 8 shows an exploded view of a mechanism shown in FIG. 7 accordingto an embodiment of the invention;

FIG. 9 shows an enlarged view of a portion of an elevated platformapparatus depicting various components and mechanisms to an embodimentof the invention;

FIGS. 10A and 10B show a reverse perspective view and a side view of acomponent of the elevated platform apparatus shown in FIG. 1;

FIGS. 11A-11C show additional components incorporated into an elevatedplatform apparatus according to an embodiment of the invention; and

FIG. 12 shows an elevated platform apparatus in accordance with anotherembodiment of the invention.

DETAILED DESCRIPTION OF THE INVENTION

Referring to FIGS. 1-3, an elevated platform apparatus 100 is shown(referred to herein as the “apparatus” for purposes of convenience). Theapparatus 100 includes a first assembly 102 having a first pair ofspaced apart rails 104A with a plurality of rungs 106A extendingbetween, and coupled to, the rails 104A. The rungs 106A aresubstantially evenly spaced, parallel to one another, and are configuredto be substantially level when the apparatus 100 is in an orientationfor intended use, so that they may be used as “steps” for a user toascend (or descend) the apparatus 100. The first pair of rails 104A andtheir associated rungs 106A may be referred to as an outer railassembly. The first assembly 102 may further include a second pair ofspaced apart rails 104B with a plurality of rungs 106B extendingbetween, and coupled to, the rails 104B. Again, the rungs 106B areevenly spaced, parallel to one another, and are configured to besubstantially level when the apparatus 100 is in an orientation forintended use so that they, too, may be used as steps for a user toascend (or descend) the apparatus 100. The second pair of rails 104B andtheir associated rungs 106B may be referred to as an inner railassembly. The inner rail assembly is slidably coupled with the outerrail assembly such that the overall height of the assembly 102 may beselectively adjusted by a user. When the first assembly 102 is in agenerally contracted state (exhibiting a shorter height), at least someof the rungs 106B of the inner rail assembly are adjacent to, andaligned with, at least some of the rungs 106A of the outer railassembly. Thus, a rung 106A from the outer rail assembly and an alignedrung 106B from the inner rail assembly may cooperatively form a common“step” when a user is ascending or descending the apparatus 100 with thefirst assembly 102 in such a contract stated. On the other hand, whenthe first assembly 102 is in an extended state (exhibiting a relativelytaller height), one or more of the rungs 106B of the inner rail assemblymay be displaced upwardly from rungs 106A of the outer rail assembly,acting as their own, independent step, effectively providing more stepsfor a user to ascend.

The apparatus 100 also includes a second assembly 108 that may beconfigured similarly to the first assembly. For example, the secondassembly 108 may include a first pair of spaced apart rails 110A with aplurality of rungs 112A extending between, and coupled to, the spacedapart rails 110A. The first pair of rails 110A and their associatedrungs 112A may be referred to as an outer rail assembly. The secondassembly 108 may further include a second pair of spaced apart rails110B and a plurality of rungs 112B extending between, and coupled to,the rails 112B. The second pair of rails 110B and their associated rungs112B may be referred to as an inner rail assembly. As with the firstassembly 102, the inner rail assembly of the second assembly 108 isslidably coupled with the outer rail assembly of the second assembly 108such that the overall height of the assembly 108 may be selectivelyadjusted by a user. In some embodiments, rather than rungs 112A and112B, bracing or other structural components may be used to coupleassociated rail pairs (110A or 110B) and provide a desired level ofsupport and strength to the spaced apart rails 110 of the secondassembly.

The first and second assemblies 102 and 108 may be formed of a varietyof materials and using a variety of manufacturing techniques. Forexample, in one embodiment, the rails 104A, 104B, 110A and 110B may beformed of a composite material, such as fiberglass, while the rungs andother structural components may be formed of aluminum or an aluminumalloy. In other embodiments, the assemblies 102 and 108 (and theirvarious components) may be formed of other materials including othercomposite materials, plastics, polymers, metals, metal alloys orcombinations of such materials. Additionally, in one embodiment, therungs may be coupled with their associated rails in a manner such asdescribed in U.S. Pat. No. 7,086,499 entitled LIGHT WEIGHT LADDERSYSTEMS AND METHODS, the disclosure of which is incorporated byreference herein in its entirety.

The assemblies 102 and 108 may be coupled to one another by way of apair of hinges 114 enabling them to extend into a deployed condition(FIG. 1) where they are positioned such that their lower ends are spacedapart from one another (creating a stable base for the apparatus 100),and collapse into a stowed condition where their lower ends arepositioned relatively close to one another (FIG. 3—with FIG. 2 showing atransition between the states or conditions shown in FIGS. 1 and 3). Asnoted above, the first and second assemblies 102 and 108 may beindependently adjustable such that they each may extend to varyingelevations enabling the overall height of the apparatus to beselectively adjusted. Such assemblies 102 and 108 may be constructed,for example, as described in U.S. Pat. No. 4,182,431, entitledCOMBINATION EXTENSIONS AND STEP LADDER RUNGS THEREFOR, the disclosure ofwhich is incorporated by reference herein in its entirety.

Adjustment mechanisms 116 may be associated with either or both of theassemblies 102 and 108 to enable elevation or height adjustment of suchassemblies. The adjustment mechanism 116 may be similar to thatdescribed in the aforementioned U.S. Pat. No. 4,182,431, or it may be ofa different configuration. Another example of an adjustment mechanism(such as is depicted in FIGS. 1-3) is described in U.S. PatentApplication Publication No. 2009/0229918 (U.S. application Ser. No.12/399,815) entitled LADDERS, LADDER COMPONENTS AND RELATED METHODS, thedisclosure of which is incorporated by reference herein in its entirety.

A platform or deck 120 is associated with the rail assemblies 102 and108 and may rest on the uppermost rungs, or other associated structure,of the assemblies 102 and 108 when the apparatus 100 is in a deployedcondition (see FIG. 1). In the embodiment shown in FIGS. 1-3, theplatform is rotatably coupled with the first assembly 102 (e.g., withthe pair of rails 104B of the inner rail assembly) and selectivelyengages the second assembly 108 to lock the platform 120 in a workingposition as shown in FIG. 1. When in the working or deployed state, theplatform 120 provides an enlarged area or support surface for a workerto stand on comfortably and safely so that they can work at the highestsupport position of the apparatus 100.

A safety enclosure, referred to herein as a cage 122, may be formedabout the platform to encompass a worker while standing on the platform120. When designed appropriately, the provision of a cage may precludethe necessity of a worker needing to wear a harness and “tie off” whileworking on the apparatus. The cage 122 may include a first bar 124positioned at a first elevation that extends around most (e.g., threesides) of the perimeter of the work space defined by the platform 120.The cage 122 may also include a second bar 126 positioned at a second(higher) elevation that extends around most of the perimeter of the workspace defined by the platform 120. One or more gates 128 may be locatedon one side of the cage 122 and configured to enable a user to climb thefirst assembly 102 and pass through the gates 128 with the gates 128closing behind the user as he or she stands on the platform 120. Anumber of components of the cage 122 may be coupled together usinghinges or pivoting joints enabling them to be deployed, as shown in FIG.1, and collapsed as indicated in FIGS. 2 and 3. For example, the bars124 and 126 may be pivotally or hingedly coupled with extensions 132coupled with the first assembly 102, or may be coupled to rails (e.g.,rails 104A) of the first assembly 102. Similarly, the bars 124 and 126may be pivotally coupled relative to the gate members 128.

The gates 128 may be configured, for example, to swing or pivot inwardlyas the user pass through them from the rungs 106 of the first assembly102 to the platform 120, automatically swing back to the position shownin FIG. 1 (through the use of springs or other biasing mechanisms oractuators), and then resist any force applied to it in an outwarddirection to prevent a user from inadvertently stepping back through thegates 128 and falling from the platform 120. A user may pull the gates128 inwardly and pass through them from the platform 120 to the rungs ofthe first assembly 102 to exit the cage 122 and descend from theplatform 120.

Referring briefly to FIG. 4, an example is shown of self returning gates128 according to one embodiment of the invention which largely usesgravity to bias the gates into the closed position (i.e., the positionshown in FIG. 1). Each of the gates 128 are rotatably coupled with anassociated post member 130 positioned adjacent to an extension member132 projecting from the first assembly 102. One or more of theconnections between the gates 128 and their associated post member 130may include a pair of collars 134A and 134B. The pair of collars 134Aand 134B may each include mating inclined engagement surfaces 136A and136B. When the gates 128 are rotated inwardly (i.e., as a user pushesthe gates 128 to pass through onto the platform 120), the rotation ofthe upper collar 134A relative to the lower collar 134B causes the uppercollar 134A (and the associated gate 128) to be displaced slightlyupwardly (relative to the lower collar 134B). With the upper collar 134Ain the rotated position (i.e., with the gate 128 opened inwardly), theweight of the gate 128 pushes down through the inclined surface 136A ofthe upper collar 134A on to the inclined surface 136B of the lowercollar 134B causing the gate 128 and upper collar 134A to rotate back totheir “closed” position. Of course, other mechanisms may be used inplace of, or in addition to, that shown in FIG. 5 to bias the gates 128to their closed positions.

Returning to FIGS. 1-3, the upper bar 126 may be positioned at a height,for example, that is between the waist height and the chest height of anaverage user (e.g., between approximately 3 feet and 5 feet above theplatform 120). In one embodiment, the height of the upper bar 126 (aswell as the lower bar(s) 124) may be adjustable to accommodate users ofvarying heights. In such a case, a minimum height may be defined perrelevant safety standards or in accordance with appropriate designconsiderations. Additionally, in one embodiment, either or both of thebars 124 and 126 may be enlarged relative to the perimeter of theplatform 120 such that the volume defined by the cage is larger thanjust the volume that would be defined by the perimeter of the platform122 extended upwards. In other words, while a user may be able to standon a relatively small surface area, the rest of the user's body may needmore space to move about, especially if the user is wearing a tool beltor carrying other equipment needed to accomplish their task.

Stated another way, the perimeter of the upper portion of the cage 122(such as may be defined by tracing a path starting at a first end 140 ofthe upper bar 126, following the upper bar 126 around to its second end142, and then across the gates 128 back to the first end 140 of theupper bar 126) is larger than the perimeter of the platform 120.Similarly, the area bound by the perimeter of the upper portion of thecage 122 in such an embodiment is larger than the area that is bound bythe perimeter of the platform 120.

The upper bar 126 may be pivotally coupled to the extension members 132extending from the rails 104 of the first assembly 102 above the hinges114. It is noted that the extension members 132 may be integral with theassociated rails 104 (e.g., with the rails 104A of the inner railassembly), or they may be separate members coupled with the railsthrough appropriate means. The lower bar 124 may be pivotally coupled tothe extension members 132 or it may be coupled to the rails 104depending on the height of the bar 124 relative to the platform 120.

As may be seen in FIG. 5, the cage 122 may include netting or othercomponents to form a flexible barrier 144 about at least a portion ofthe perimeter of the cage 122 to further confine a user within the cage122. For example, as shown in FIG. 6, the flexible barrier 144 mayinclude netting extending generally between the platform 120 and thelower bar 124 and may extend about the sides of the cage 122 while notimpeding the entrance through the gates 128. The flexible barrier mayprovide additional security in preventing a user from placing a foot orleg through the space defined between the platform 120 and the lower bar124. If desired, such a flexible barrier 144 may be extended further,for example, up to the upper bar 126.

Referring to FIG. 6, a lock 152 may be associated with the platform 120such that when the apparatus 100 is deployed (in the condition shown inFIG. 1), the platform 120 is secured in place and the apparatus is in astable condition with the assemblies fixed in relative position to oneanother. A pair of locks 152 may be used with one being positioned oneach side of the platform 120, preventing it from folding into acollapsed state until both locks 152 are independently actuated by auser. In the embodiment shown, the locks 152 include a lever 154 that isrotatably coupled with the platform 120 and biased into catching- orlocking-engagement with a shoulder 156 or other protrusion associatedwith the second assembly 108 (e.g., by way a spring or other biasingmember). Application of force to the lever 154 of the lock 152 by a usercan overcome the biasing force such that the lock or locks 152 disengagethe shoulder 156 and enable the platform 120 to rotate upwards and intoa collapsed state such as shown in FIGS. 2 and 3.

The apparatus 100 may further include wheels 160 associated with eitheror both of the assemblies 102 and 108. In one embodiment, as seen inFIGS. 1-3, a first set of wheels 160 may be coupled with the secondassembly 108 at a fixed location and be configured such that they do nottouch the ground when the apparatus 100 is in a deployed condition asshown in FIG. 1, but are configured to engage the ground when theapparatus is collapsed (FIG. 3) and then tilted beyond a given angle.This enables the wheels 160 to be used to rolling the apparatus (e.g.,such as by being dragged by a user) when in a collapsed state, whilepreventing the apparatus 100 from rolling on the wheels 160 when it isin a deployed condition.

Feet 170 may be coupled to the bottom of the rails and have appropriateengagement surfaces associated therewith to provide the apparatus 100with the desired friction and stability when placed on a supportingsurface. In one embodiment, the feet 170 may be configured to “snap-on”to the associated rail. For example, the feet 170 (or a combination ofthe feet and the wheels 160) may be manufactured and assembled asdescribed in U.S. Provisional Patent Application No. 61/445,387 entitledLADDERS, LADDER COMPONENTS AND RELATED METHODS (Attorney Docket No.59714.0150), the disclosure of which is incorporated by reference hereinin its entirety.

In another embodiment, retractable wheels 172 may be associated thefirst assembly 102, the second assembly 108 or both, in place of, or inaddition to, the wheels 160 discussed above. For example, as shown inFIG. 7, retractable wheels 172 may be coupled to the first assembly 102(in addition to fixed location wheels 160 such as described above).While specifically shown in association with the first assembly 102 inFIG. 8, a first pair of retractable wheels 172 may be coupled to thefirst assembly 102 and a second pair of retractable wheels 172 may becoupled with the second assembly. When in a deployed state, theretractable wheels 172 may engage the ground or other supporting surfacesuch that the first and second assemblies 102 and 108 are lifted abovethe ground and the apparatus 100 may be maneuvered from one location toanother by rolling it about on the retractable wheels 172. Once theapparatus is in a desired position on a supporting surface, theretractable wheels 172 may be retracted to a stored state so that thefeet 170 of the apparatus may rest securely on the ground or othersupporting surface.

In one embodiment, each of the retractable wheels 172 (e.g., four, withtwo being associated with each assembly 102 and 108) may be capable ofindependent actuation rather that relying on a single mechanism todeploy or retract the set of wheels simultaneously. Such may help toprevent the inadvertent deployment of wheels during use of the apparatus100, since independent actuation would require a more affirmative act.

Various types of actuating mechanisms may be used for deploying andretracting the wheels 172. For example, in one embodiment, the wheels172 may be constructed with a biasing element that, when subjected onlyto the weight of the apparatus 100, enables the wheels to be deployedsuch that the apparatus may be rolled from one position to another,while, when a user climbs onto the apparatus 100, the additional weightof the user causes the wheels 172 to retract so that the feet 170 engagethe ground and stabilize the apparatus 100.

In another embodiment, the retractable wheels 172 may include acam-follower retraction mechanism similar to what is found in manyretractable ball-point pens. For example, referring to FIG. 8, anexploded view of a retraction mechanism 174 is shown. The mechanism 174includes a housing 176, a cam sleeve 178 having a plurality of axiallyextending slots 180 circumferentially disposed about an interior surfacethereof and formed between a plurality of cam features 182 having angledengagement surfaces 184 formed at their lower ends. The mechanismfurther includes a push rod 186 having an undulating engagement surface188 and a plurality of fins 190 as well as a cam follower 192 having aplurality of fins 194, with each fin 194 having an angled engagementsurface 196. The mechanism 174 further includes one or more springs 198,end caps 200, a mounting plate 202 for mounting to the wheel 172 orcaster, and a plurality of fasters 204 to couple the various componentstogether in a desired configuration.

The fins 190 of the push rod 186 are positioned within correspondingslots 180 of the cam sleeve 178 such that the push rod 186 may beaxially displaced within the cam sleeve 178 along an longitudinal axisbut not rotate within the cam sleeve about the longitudinal axis. Thecam follower 192 is configured so that its engagement surfaces 196engage the undulating engagement surface 188 of the push rod 186 andselectively engage the engagement surfaces 184 of the cam features 182.When not engaged with the engagement surfaces 184 of the cam features182, the fins 194 of the follower are disposed within the slots 180 sothat the follower may be displaced upwardly within the cam sleeve 178.

In operation, a user may lift up on a corner of the apparatus (e.g., sothat a foot 170 adjacent the retractable wheel 172 is displaced off ofthe ground) and push down on the mounting plate 202. Assuming that themechanism 174 is in a retracted state (i.e., with the wheel or casterdisplaced upwards), this causes the fins 194 of the cam follower 192 todisengage the slots 180 of the cam sleeve 178 while the undulatingsurface 188 of the push rod 190 effects a rotation of the cam follower192 such that when the user removes their foot (i.e., removesapplication of force to the lower portion of the mechanism 174), thespring 198 pushes the cam follower 192 upwards causing its engagementsurfaces 196 to abut the engagement surfaces 184 of the cam features182. This places the cam follower 192, push rod 186 and, ultimately thewheel 172 or caster in a lower axial position relative to the cam sleeve178 and housing 178 such that the wheel is “deployed” and may engage theground instead of the foot 170 that is adjacent the retractable wheel172. Pushing down on the mounting plate 202 again causes the camfollower 192 to disengage the cam features 182 and enables it to returnto its prior axial position with the fins 194 disposed within slots 180of the cam sleeve 178, placing the wheel in a retracted position. Thus,each retractable wheel 172 may be independently, selectively actuated asnoted above. With all of the retractable wheels 172 in a deployed state,the apparatus 100 may be easily wheeled to a new location whilemaintaining the entire apparatus in a deployed state (i.e., in the stateshown in FIG. 1) without collapsing the apparatus (i.e., the state shownin FIG. 3). When the apparatus 100 is in a desired location, the usermay retract each wheel 172 such that all of the feet 170 rest on theground or other supporting surface.

It is noted that various combinations of actuators or mechanisms may beused and that all of the retractable wheels 172 need not use the sametype of mechanism. For example, a mechanism such as shown in FIG. 8 maybe used with the retractable wheels 172 associated with the firstassembly 102 while other mechanisms (e.g., those that deploy and retractbased on applied weight, as described above) may be used with theretractable wheels 172 associated with the second assembly 108.Additionally, as previously noted, the retractable wheels 172 need notreplace the wheels 160 that are placed in a fixed location on one of theassemblies (i.e., 102 or 108). Instead, the apparatus 100 may include,for example, a total of six or more wheels with two or more wheels usedfor transporting the apparatus 100 when in a collapsed state (i.e.,wheels 160) and four or more wheels for selective deployments andretraction that may be used to maneuver the apparatus 100 when it is ina deployed or “in-use” state (i.e., retractable wheels 172).

Another feature that may also be included with the apparatus 100 is astabilizer mechanism. For example, stabilizers or outrigger mechanismsmay be associated with the first assembly 102, the second assembly 108,or both, to provide a wider support base and provide greater stabilityto the apparatus 100. Such stabilizers may also enable the apparatus 100to be placed in areas having relatively uneven ground wherein thestabilizers adjust to compensate for such unevenness. Referring brieflyto FIG. 9, a stabilizer 220 is shown in association with a rail 110A ofthe second assembly 108 of an apparatus 100. The stabilizer 220 includesa first swinging arm 222 having one end pivotally coupled with the rail110A and having an adjustment mechanism 224 that enables the length ofthe swing arm 222 to be selectively adjusted. For example, the swingingarm 222 may include tubular members (of circular or polygonal crossshape) with one being telescopingly disposed within the other. Theadjustment mechanism 224 may include a locking pin or detent mechanismto enable the selective locking of the two tubular members at one ormore desired positions relative to each other. The second end of thefirst swinging arm 222 is pivotally coupled to a second swinging arm226. The second swing arm 226 has a first end pivotally coupled with therail 110A at a location spaced from the connection of the first swingingarm 222. The second swinging arm 226 is also adjustable in length with afoot 228 or traction member disposed at its lower end for engaging theground or other support surface. In one embodiment, the second swingingarm 226 may include two tubular members with one being telescopinglydisposed within the other. The second swinging arm may further include amechanism to enable the selective adjustment of such tubular armsrelative to each other. For example, as will be appreciated by those ofordinary skill in the art, a mechanism may be used so that rotation ofthe lower tubular member relative to the upper tubular member in onedirection “locks” the two members relative to each other, while rotationin the other direction “unlocks” the members and enables the lowertubular member to slide in and out of the upper tubular member to adjustthe overall length of the swinging arm 226. Such a configuration enablesthe adjustment of the second swinging arm to be non-incremental (i.e.,allowing any length of the second swinging arm between a defined maximumand a defined minimum).

While a single stabilizer 220 is shown in FIG. 9, it will be understoodthat a second stabilizer may be coupled with the corresponding rail, ofthe pair of rails 110B, for the second assembly 108. Additionally, whileshown in association with the second assembly 108, such a stabilizermechanism may be used in association with the first assembly 102, or inassociation with both the first assembly 102 and the second assembly108.

Referring now to FIGS. 10A and 10B, a reinforcing bracket 240 is shownin accordance with an embodiment of the invention. The reinforcingbracket may be positioned on the upper ends of the external rails (104Aand 110A) of the two assemblies (102 and 108). For purposes ofsimplicity, reference will be made to rail 104A in the followingdescription. The bracket 240 may wrap around all four corners of therail 104A. However, the bracket 240 is discontinuous on the interiorside of the rail 104A. Although discontinuous along the interior side,the bracket 240 wraps around the interior corners of the rail 104A andextends along an interior surface of the inner rails 104B, thussubstantially circumscribing or “enclosing” the inner rail 104B withinthe bracket 240. The bracket 240 reinforces the upper portion of therail 104A, which is generally formed as a C-channel shape, so that theupper end of the outer rail 104A does not splay or spread outward (awayfrom engagement with the inner rail 104B) when a load is applied to therail 104A during use of the apparatus 100 (including when a force isapplied to the adjustment mechanism 116 used to adjust the height of anassociated assembly). The discontinuous nature of the bracket 240defines a slot 242 through which various components (e.g., inner rungs106B, support brackets 244, etc.) may pass through when the inner rails104B are slidingly displaced relative to the outer rails 104A to adjustthe height of the assembly 102.

While the apparatus shown in FIG. 1 shows a certain number of outerrungs 106A and inner rungs 106B, it is noted that the present apparatusmay be configured at a variety of heights, with any number of rungs(inner and outer). As such, in configurations where the assemblies 102and 108 are relatively tall, and include numerous rungs, it may becomedifficult to adjust the inner rails (104B and 110B) relative to theouter rails (104A and 110B) due to their height and orientation. Assuch, one or more pulley systems, or other adjustment systems, may beused. For example, referring now to FIGS. 11A-11C, a pulley system 260is shown in accordance with an embodiment of the invention. Eachassembly 102 and 108 includes its own pulley system for independentselective adjustment of the assembly. As seen in FIGS. 11A and 11C, agiven system 260 may include a rope 262, cable or other tension line fedthrough a first pulley 264 that is coupled with the outer rails (104A or110A), a bracket or some other portion of the outer rail assembly. Therope 262 may be fed through a second pulley 266 which is coupled with aninner rail (104B or 110B) or to, bracket or other component associatedwith the inner rail assembly, as shown in FIG. 11B. One end of the rope262 is coupled with an outer rail assembly (e.g., outer rails 104A or110A) as indicated at 268 in FIG. 11C.

In operation, when it is desired to raise an assembly (e.g., 102) to anincreased height, a user may actuate the adjustment mechanisms 116associated with the assembly 102 to enable sliding displacement of theinner rails 104B relative to the outer rails 104A, and then pull thefree end of the rope 262 (i.e., apply a tensile force to the rope 262from the free end). This causes the rope to pull upward on the secondpulley 266 causing the inner rails 104B (and associated rungs 106B andother components, including the platform 120 and cage 122 components) tobe displaced upward relative to the outer rails 104A. Once at a desiredheight, the adjustment mechanisms 116 may again be actuated to lock theinner rails 104B relative to the outer rails 104A. A similar process maybe used in adjusting the assembly to a lower height by allowing the freeend of the rope 262 to slowly be displaced back through the first pulley264 while keeping the rope 262 relatively taut.

Referring again to FIG. 11A, a bracket 270 may be coupled to each outerrail 104A and 110A adjacent the location of the adjustment mechanisms116. Not only does the bracket help to provide structural support to theassemblies 102 and 108, but also serves as a safety barrier to prevent auser from pinching or smashing their fingers during use of theapparatus—specifically during actuation of the adjustment mechanisms116. For example, when actuating an adjustment mechanism, a user maytend to place the palm of their hand on the lower portion of the leverof the adjustment mechanism 116, wrapping their fingers around the backside of the outer rail (104A or 110A) and along the interior side of therails. If a user keeps their fingers in this position after actuatingthe adjustment mechanisms 116, their fingers may get caught or smashedby components associated with the inner rails 104B or 110B as they sliderelative to the outer rails 104A and 110B (e.g., inner rungs 106B and112B, brackets, etc.). The placement of the brackets 270 on the backside of the rails (i.e., the side facing the other assembly) at alocation that is adjacent the adjustment mechanisms helps to prevent auser from wrapping their fingers around the outer rails 104A and 110A,eliminating, or at least reducing, the risk of potential injury to theuser's hands.

Referring now to FIG. 12, another embodiment of an apparatus 300 isshown. The apparatus 300 is generally similar to the previouslydescribed apparatus 100, including a first assembly 102 and a secondassembly 108, with their various components, as well as a platform 120.However, the apparatus 300 includes not only a first set of gates 128,but a second set of gates 302 on the opposing side of the platform 120.The second set of gates 302 may be pivotally coupled with variouscomponents of the cage 122 (e.g., the upper and lower bars 304 and 306)and may function similarly to the first set of gates 128 as describedabove. The second set of gates 302 enable a user to access the platform120 of the apparatus 300 by climbing the rungs of either assembly 102 or108, providing greater efficiency and functionality to a user of theapparatus 100.

While the invention may be susceptible to various modifications andalternative forms, specific embodiments have been shown by way ofexample in the drawings and have been described in detail herein.However, it should be understood that the invention is not intended tobe limited to the particular forms disclosed. Rather, the inventionincludes all modifications, equivalents, and alternatives falling withinthe spirit and scope of the invention as defined by the followingappended claims.

What is claimed is:
 1. An elevated platform apparatus comprising: afirst rail assembly having a pair of rails coupled with a plurality ofrungs; a second rail assembly, an upper end of the second rail assemblybeing hingedly coupled with the first rail assembly, the first railassembly and the second rail assembly being selectively positionablerelative to each other between a deployed state and a collapsed state; aplatform pivotally coupled with the first rail assembly and configuredto extend between spaced apart portions of the first assembly and thesecond assembly when they are in the deployed state; a cage including atleast one frame member and a pair of gates collectively forming abarrier substantially surrounding an area above the platform when thefirst and second assemblies are in the deployed state and when the pairof gates are in a closed position, wherein the pair of gates extendtowards each other when in the closed position, the pair of gates beingselectively positionable from the closed position to an open positionwherein the gates are rotated inwardly such that a portion of each gateof the pair extends into the area surrounding the platform, and whereineach of the pair of gates is limited from rotating outwardly away fromthe area above the platform beyond the closed position; and wherein,when the first rail assembly and the second rail assembly are in thecollapsed state, the platform is positioned adjacent the pair of gates.2. The apparatus of claim 1, further comprising a locking memberconfigured to releasably lock a the platform with the second railassembly when the first and second assemblies are in the deployed state.3. The apparatus of claim 1, wherein the pair of gates are biasedtowards the closed position.
 4. The apparatus of claim 1, wherein thefirst rail assembly includes an outer rail assembly and an inner railassembly slidingly coupled with the first rail assembly.
 5. Theapparatus of claim 4, further comprising at least one adjustmentmechanism configured to selectively lock the inner rail assembly at aspecified location relative to outer rail assembly.
 6. The apparatus ofclaim 5, further comprising a pulley system associated with the firstassembly and configured to assist adjustment of the inner rail assemblyrelative to the outer rail assembly.
 7. The apparatus of claim 6,wherein the second rail assembly includes outer rail assembly and aninner rail assembly slidingly coupled with the first rail assembly. 8.The apparatus of claim 7, further comprising at least one otheradjustment mechanism configured to selectively lock the inner railassembly of the second assembly at a specified location relative toouter rail assembly of the second assembly.
 9. The apparatus of claim 1,further comprising at least one pair of wheels coupled with theapparatus.
 10. The apparatus of claim 9, wherein the at least one pairof wheels includes: a first pair of wheels coupled with at least one ofthe first assembly and the second assembly at a fixed location; a secondpair of wheels coupled with the first assembly, the second pair ofwheels including at least one retraction mechanism; a third pair ofwheels coupled with the second assembly, the third pair of wheelsincluding at least one retraction mechanism.
 11. The apparatus of claim10, wherein the first pair of wheels are positioned such that they donot contact a supporting surface when the apparatus is positioned on thesupporting surface in a deployed state and in an orientation of intendeduse.
 12. The apparatus of claim 1, wherein the at least one frame memberincludes a first frame member and a second frame member.
 13. Theapparatus of claim 11, wherein the first frame member is positioned at afirst height above the platform when the first and second assemblies arein the deployed position and wherein the second frame member ispositioned at a second height above the platform when the first andsecond assemblies are in the deployed position, the second height beinggreater than the first height.
 14. The apparatus of claim 12, furthercomprising a flexible material extending upward from the platform to atleast the first frame member.
 15. The apparatus of claim 1, furthercomprising at least one adjustable stabilizer coupled with at least oneof the first rail assembly and the second rail assembly.